International Research Journal of Engineering and Technology (IRJET)
e-ISSN: 2395-0056
Volume: 06 Issue: 07 | July 2019
p-ISSN: 2395-0072
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Methods of Voltage Regulation for Radial DC- Microgrid
Ms. Nikita D. Sapkar1, Prof. V. R. Aranke2
1PG
Student, Department of Electrical Engg, MCOERC, Eklahare, Nashik, (MS) India
Profecessor, Department of Electrical Eng, MCOERC, Eklahare, Nashik, (MS) India
---------------------------------------------------------------------***---------------------------------------------------------------------2Associate
Abstract - The power generation from renewable power sources is variable in nature, and may contain unacceptable fluctuations
in case of the wind power generation. High fluctuations in power generation may negatively impact the voltage stability of the
microgrid. Various control methods are discussed on the coordinated operation of the DG’s for a single bus system, which have their
own merits and limitations. Droop control method is used for constant voltage but it is having some limitations. Modified droop
control technique utilize dc bus signalling and adaptive adjustment of droop co-efficients. All these systems focused only on one bus
system. The voltage drop problem in DC grid can be eliminated by placing the DG in the bus. The DG is supplying part of the load
power and hence reduces the voltage drop along line. Series voltage Regulator dynamically injects voltage in series with the dc
microgrid. The SVR uses a dual active bridge dc-dc converter followed by a full-bridge dc-dc converter. DAB provides unipolar DC
voltage. The dc-dc converter in second stage regulates output voltage as per requirement. As a result, the voltage level at the
different points of the grid becomes independent of load variation and stays within the specified limit. In this work, the voltage
regulator is connected at the mid-point of the grid, but it may be connected in some other locations to get optimal rating of the
same. The simulations are carried out using MATLAB software. The results show the effectiveness of such voltage regulator for
radial dc microgrid, especially under critical load condition.
Key Words: Series Voltage Regulator, Dual Active Bridge, DC-DC Converter etc.
1. INTRODUCTION
Due to increase in demands on energy, renewable energy has attracted extensive interest. Distributed generation has
number of advantages as compared to the centralised power generation. Because cenratralised power generation units
construction is complicated, it’s cost is more as compared to the distributed generation units. After connecting distributed
generation with local loads and energy storage, a microgrid is formed. There are two types of microgrid ac and dc. DC
microgrids does not required frequency, phase or reactive power control. DC system is used for developing rural area and small
scale commercial facilities such as data center, residential buildings. For voltage regulation purpose number of methods are
used droop control method is one of them. But it is having disadvantages such as current drop. Droop index is introduced to
minimize this problem. In this paper co-ordination of DAB and DC-DC converter is used .Dual Active Bridge provides constant
DC output and with the help of dc-dc converter adjustable output voltage is provided.
2. RELATED WORK
2.1 SIMULINK Model
The simulation for SVR is explained here. A solar plate of 250W is connected to it’s input side. Stray capacitances are
connected for removing ripples contents at the output side. Subsystem consists of full bridge rectifier. It is the combination of
thyristors and linear transformer. Here transformer is used for isolation purpose. On the output side load of 400V is connected.
Figure 1.1 shows SIMULINK Model of SVR.
Figure 1.1: SIMULINK Model for SVR
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International Research Journal of Engineering and Technology (IRJET)
e-ISSN: 2395-0056
Volume: 06 Issue: 07 | July 2019
p-ISSN: 2395-0072
www.irjet.net
2.2 Rating of the components
Parameters of PV Array
Module Type
Trina solar TSM-250PA05.08
Number of cells per module
60
Number of series connected modules per string
14
Number of parallel strings
1
Module specifications
Voc
37.6
Isc
8.55
Vmp
31
Imp
8.06
Series resistance, Rs ohms
0.247
Diode saturation current
2.038
Diode quality factor
0.99766
2.3 Simulation Results:
Figure 1.2: SVR output voltage
Here output voltage is 400V, so that we get constant voltage as compared to existing system. That is this system is more stable.
Figure 1.3: (a) Simulation result of SVR input voltage
Figure 1.4: (b) Simulation result of Grid Current
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International Research Journal of Engineering and Technology (IRJET)
e-ISSN: 2395-0056
Volume: 06 Issue: 07 | July 2019
p-ISSN: 2395-0072
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As shown in above figures input is given to the above circuit and we get constant output. That is system is giving
constant output, means satisfactory performance is there.
3. CONCLUSION
In this paper the working details of SVR is explained, here SVR is the combination of DAB and full bridge converter. With the
help of this simulation we get constant output voltage. Also, it’s performance is checked through simulation. It also indicates the
impacts of connecting different loads such as resistive load and inductive load.
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